Chip Substrate Provided with Joining Grooves in Lens Insert

ABSTRACT

A chip substrate includes: a plurality of conductive layers horizontally stacked and constituting the chip substrate; a plurality of insulation layers alternately with the conductive layers and electrically separating the conductive layers; a lens insert comprising a groove having a predetermined number of edges on the upper surface of the chip substrate and having a cross-section wherein an arc is formed at the region where the extended edges meet; a cavity comprising a groove reaching down to a predetermined depth towards the area accommodating the insulation layer within the internal region of the lens insert; and a plurality of joining grooves formed on the surface of the lens insert. Thus, the lens to be inserted also can be formed to be a shape comprising straight lines so that the manufacturing process of the lens to be inserted into the chip substrate can be further simplified.

CROSS-REFERENCE TO RELATED PATENT APPLICATION

This U.S. non-provisional patent application claims priority under 35U.S.C. §119 of Korean Patent Application No. 10-2015-0000026 filed onJan. 2, 2015 in the Korean Patent Office, the entire contents of whichare hereby incorporated by reference.

BACKGROUND

1. Technical Field

The present invention relates to a chip substrate and a method formanufacturing same, more particularly, relates to a chip substrateprovided with joining grooves in lens insert.

2. Description of the Related Art

Traditionally, a chip mounting space in a chip substrate has been formedon the upper surface of the chip substrate using a mechanical machiningor a chemical etching process. When an optical device chip such as a UVLED is being mounted in such a chip substrate, a downwardly narrowingspace has been formed in order to enhance the optical reflectioncapability. After forming such a space, the chip is mounted and a lensis formed when sealing the mounting space, thereby enhancing the opticalefficiency.

At this time, when forming the lens, since the mounting space is formedto have a circular shape when viewed from the upper surface of the chipsubstrate, the shape of the lens is formed to have a circular shapecorresponding thereto. However, in order to machine the lens preciselyto be a circular shape, there have been difficulties in manufacturingprocess compared to machining of a lens formed with straight lines of arectangle or a triangle.

Furthermore, in bonding the lens there has been a problem that thesealant is being overflowed and penetrating into the light emittingsection of the chip substrate.

SUMMARY

In accordance with exemplary embodiments of the invention, a structurefor a chip substrate is configured with a space for lens insertion isformed to be a shape comprising straight lines.

Further embodiments include a structure which is capable ofaccommodating the overflowing adhesive by providing a plurality ofjoining grooves inside the lens insert.

A chip substrate provided with joining grooves inside the lens insertaccording to an exemplary embodiment of the present invention forsolving the above described technical problems includes: a plurality ofconductive layers horizontally stacked and constituting the chipsubstrate; a plurality of insulation layers alternately with theconductive layers and electrically separating the conductive layers; alens insert comprising a groove having a predetermined number of edgeson the upper surface of the chip substrate and having a cross-sectionwherein an arc is formed at the region where the extended edges meet; acavity comprising a groove reaching down to a predetermined depthtowards the area accommodating the insulation layer within the internalregion of the lens insert; and a plurality of joining grooves formed onthe surface of the lens insert.

The chip substrate further includes a first metal pad formed on a unitarea on the conductive layers being separated by at least one of theinsulation layers inside the cavity.

The chip substrate further includes a second metal pad beingsuccessively formed on the plurality of insulation layers separated fromthe plurality of insulation layers inside the cavity.

The joining grooves include: a first joining groove being formedsurrounding the outer area of the cavity on the surface of the lensinsert; and a second joining groove being formed surrounding the firstjoining groove.

The chip substrate further includes a heat radiating portion beingattached to the bottom surface of the chip substrate.

The chip substrate further includes a plurality of marking portions toindicate the unit areas inside the cavity

The chip substrate further includes an electrode marking portion toindicate an electrode for at least any one conductive layer separatedfrom the conductive layers by the insulation layer on the upper surfaceof the chip substrate.

The chip substrate further includes a plurality of side grooves, at theside surfaces of the chip substrate, inwardly concave and accommodatingthe insulation layers.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of a chip substrate provided with aplurality of joining grooves inside the lens insert according to anexemplary embodiment of the present invention.

FIG. 2 is a rear view of a chip substrate provided with a plurality ofjoining grooves inside the lens insert according to an exemplaryembodiment of the present invention.

FIG. 3 is a top view of a chip substrate provided with a plurality ofjoining grooves inside the lens insert according to an exemplaryembodiment of the present invention.

FIG. 4 is a top view of a chip substrate provided with a plurality ofjoining grooves inside the lens insert according to another exemplaryembodiment of the present invention.

DETAILED DESCRIPTION OF EMBODIMENTS

Contents of the description below merely exemplify the principle of theinvention. Therefore those of ordinary skill in the art may implementthe theory of the invention in various apparatuses which are includedwithin the concept and the scope of the invention even though it is notclearly explained or illustrated in the description. Furthermore, inprinciple all the conditional terms and embodiments listed in thisdescription are clearly intended for the purpose of understanding theconcept of the invention, and one should understand that this inventionis not limited to such specially listed exemplary embodiments.

Hereinafter, a preferred exemplary embodiment according to the presentinvention will be described with reference to the accompanying drawings.For convenience sake, an LED will be explained as a chip.

In the present exemplary embodiment, in order to manufacture a chipsubstrate, conductive layers containing multiple conductive materialshaving a predetermined thickness are alternately stacked with insulationlayers interposed therebetween.

A chunk of conductive material wherein a plurality of insulation layersare arranged spaced apart is produced by applying heat and pressure asit is being stacked.

Next, the chunk of conductive material produced in such a way isvertically diced into pieces so that the insulation layers are to beincluded in each of the diced pieces, thereby completing themanufacturing of a chip substrate, wherein multiple vertical insulationlayers are arranged in parallel and spaced apart. That is, in thepresent exemplary embodiment, one direction is a vertical direction, andthe chunk of conductive material is being vertically diced with respectto the direction of stacking, thereby manufacturing chip substrates.

A lens insert and a cavity are formed in the chip substrate manufacturedby dicing according to the above described method, and thus, a chipsubstrate provided with joining grooves inside the lens insert accordingto the present exemplary embodiment is manufactured.

The chip substrate according to another exemplary embodiment may havethe shape as shown in FIG. 4, and a plurality of lens inserts andcavities may be formed in the upper surface of the chip substrate.However, for a more detailed description, a chip substrate including onelens insert or one cavity will be explained as an example. That is, achip substrate according to FIGS. 1 to 3 is a unit chip substrate, andit can be manufactured by dicing the lens inserts as a unit.

Hereinafter, with reference to FIG. 1, a chip substrate provided with aplurality of joining grooves inside the lens insert according to anexemplary embodiment will be described.

FIG. 1 is a perspective view of a chip substrate 100 according to anexemplary embodiment. Referring to FIG. 1, a chip substrate 100 beingprovided with a lens insert 140 according to an exemplary embodimentincludes, a conductive layer 110, an insulation layer 120, a cavity 130,a lens insert 140, and a plurality of joining grooves 152 and 154. Thatis, when viewing the chip substrate 100 according to an exemplaryembodiment from the top, a lens insert 140 is formed inside of therectangular chip substrate 100, and a cavity 130 is formed inside of thelens insert 140. At this time, the lens insert 140 and the cavity 130 isformed to include an insulation layer 120.

According to an exemplary embodiment, the conductive layer 110 isstacked along a ‘specific one direction’ and constitutes the chipsubstrate 100, and it will be functioning as an electrode applyingelectrical power to the chip which is to be mounted in post-processing.In here, the ‘specific one direction’ is formed along the stackingdirection of the conductive layer 110 which is being alternately stackedwith the insulation layer 120 as described above; the ‘specific onedirection’ is formed along the horizontal direction, which is thedirection of stacking, according to FIG. 1.

The insulation layers 120 are alternately stacked with the conductivelayers 110, thereby electrically separating the conductive layers 110.That is, the insulated chip substrates interposed by the insulationlayer 120 can be functioned as a positive (+) electrode terminal and anegative (−) electrode terminal respectively.

In the present exemplary embodiment, although a case wherein oneinsulation layer 120 is present between the two conductive layers 110 isdescribed as an example, configuration of a chip substrate 100comprising two insulation layers 120 formed between three conductivelayers 110 is also possible; and forming of more insulation layers 120is also possible depending on applications thereof.

The lens insert 140 is comprised of a groove having a predetermineddepth from the surface of the chip substrate 100 and downwardly formedin the area accommodating the insulation layers 120, wherein apredetermined number of edges are formed on the upper surface of thelens insert, and arcs are formed at the corners where the edges meet.

Describing more in detail with reference to FIG. 3, the lens insert 140is formed to be a groove in the region accommodating the insulationlayers 120 on the upper surface of the chip substrate 100 bysequentially stacking a conductive layer 110, an insulation layer 120,and another conductive layer 110 and so on. Specifically, thecross-sectional shape of the lens insert 140 in the present exemplaryembodiment has four edges, and arcs are formed at the four corners wherethe edges meet.

At this time, in the present exemplary embodiment, it is preferred thatthe corners are formed roundly to be an arc. In manufacturing processusing a cutting machine of rotational movement such as a milling machinefor making a groove in the chip substrate 100 in order to form the lensinsert 140, since forming a groove having a cross-section with rightangle corners is difficult, it is designed in a way that a first edge isformed through a linear movement and the cutting machine can proceed tothe next forming process through an arc having a predetermined curvaturewhen forming the next edge.

That is, a groove can more easily be formed through a continuous processby allowing the milling machine to move to the position through an arcfor forming the next edge.

More specifically, as illustrated in FIG. 3, the arc in the presentexemplary embodiment is preferred to be formed outwardly protruded fromthe region being formed by the extension lines of the edges. That is,although when the arc is formed inwardly protruded from the extensionlines of the edges the corners of the lens to be inserted must bemachined corresponding to the curvature of the arc; when the arcs isformed outwardly protruded from the region being formed by the extensionlines of the edges, even a lens having right angled corners can beeasily accommodated and the lens can be fixed through the edges.

At this time, the gap between the arc and the lens formed afterinsertion of the lens is sealed in post-processing, thereby completingthe insertion of the lens.

Although a lens insert 140 having four edges for accommodating arectangular lens has been described in the present exemplary embodiment,the number of edges can be varied depending on the usage and the shapeof the lens; arcs can be formed in some corners not every corners wherethe edges meet, and some corners in right angle can be formed at wherethe edges meet.

In addition, the lens insert 140 of the chip substrate 100 according tothe present exemplary embodiment may further include an arc (not shown)formed outwardly protruded from the edges on the upper surface of thechip substrate.

That is, as shown in FIG. 3, when using a jig or a robot not usingsuction method for moving and joining a rectangular lens, it may help inperforming the joining process smoothly, or precise joining thereof byforming arcs protruded with respect to the facing two edges of the lensinsert 140 and providing a groove for the jig in the substrate.

The chip substrate 100 according to the present exemplary embodiment mayfurther include a cavity 130 formed in the area accommodating theinsulation layers 120 inside the lens insert 140 formed according to theabove described description.

Thus, referring to FIG. 2, a lens insert 140 is formed inwardly byforming a groove having a predetermined depth in the chip substrate 100,and a cavity 130 is formed in the region deeper than the depth of thelens insert 140.

In the present exemplary embodiment, preferably the cavity is formed tohave a downwardly narrowing shape, wherein the width thereof is gettingnarrower as it travels downward direction. Since the cavity 130 isformed to have a downwardly narrowing shape in order to enhance thelight reflecting performance of the mounted chip, an outer walldiagonally slanted may be formed therein.

In addition, referring to FIGS. 1 and 3, the lens insert 140 accordingto the present exemplary embodiment may further include a first joininggroove 154 and a second joining groove 152 having a predetermined depthon the surface to be in contact with the lens when inserting the lens.

That is, in the present exemplary embodiment, the lens is bonded afterinjecting an adhesive into the space of the second joining groove 152comprising a predetermined groove in the surface of contact along thecircumference of the lens insert 140. At this time, since the adhesivemay be overflowed towards inside and outside of the joining area duringthe bonding process of the lens, another separate first groove 154 maybe provided on the bonding surface in order to prevent such overflow andto use a right amount of the adhesive.

That is, with respect to FIGS. 1 and 3, the groove close to the cavityis the first joining groove 154, and the second joining groove 152 maybe formed surrounding the first joining groove. Thus, an adhesive forbonding is injected into the second joining groove 152, and the extraadhesive being overflowed is accommodated in the first joining groove154, therefore flowing of the adhesive into the cavity can be prevented.

In addition, the chip substrate according to the present exemplaryembodiment may further include a first metal pad 160. In the presentexemplary embodiment, the first metal pad 160 is formed to have apredetermined height above the surface of each of the conductive layersseparated by the insulation portion inside the cavity 130, and bonded tothe electrode portion formed in the chip.

In the present exemplary embodiment, the first metal pad 160 is formedto have a predetermined height above the surface of each of theconductive layers 110 separated by the insulation layers 120 inside thecavity 130, and bonded to the electrode portion formed in the chip 200.

That is, the first metal pad 160 is formed on the surface of theconductive layer 110, specifically on the surface of the conductivelayer 110 corresponding to the central portion of the cavity 130referring to FIG. 3.

That is, the first metal pad 160 comprising metal such as copper isstacked, then the chip wherein an electrode portion is formed in thebottom surface thereof such as a flip chip can be directly bonded to andmounted on the first metal pad 160 which is divided by the insulationlayer 120.

In addition, according to FIGS. 1 and 3, a marking portion 170 forindicating the unit area of the metal pad for guiding the forminglocation of the first metal pad 160 may further included.

In addition, the chip substrate according to the present exemplaryembodiment may further include a second metal pad 180. The second metalpad 180 is successively formed in the area on a plurality of conductivelayers separated by a plurality of insulation layers inside of thecavity.

The second metal pad 180 can be functioning as a zener diode forprotecting the chip within the substrate designed in a serial-parallelstructure in order to mount a plurality of flip chips. Thus the secondmetal pad 180 according to the present exemplary embodiment can besuccessively formed in the area on the plurality of conductive layersseparated by the plurality of insulation layers within the cavity.

In addition, the chip substrate 100 according to the present exemplaryembodiment may further include a first metal pad 160 being formed on theupper surface of the chip substrate in order to apply electricity to theconductive layer 110.

That is, referring to FIGS. 1 and 3, electrode connecting portions 210may be formed on the upper surface of the chip substrate 100respectively for applying electricity thereto. In addition, a pluralityof electrode marking portions 220 may further be included around theelectrode connecting portions so that the electrodes can be easilyrecognized by the user.

Referring to FIG. 1, a plurality of insulation layers 120 are formedbetween a plurality of conductive layers 110 the chip substrate 100according to the present exemplary embodiment, therefore differentpolarities of electricity can be applied to both of the far endconductive layers 110 of the conductive layers 110 separated by theinsulation layers 120. As an example, the electrode of the conductivelayers 110 can be recognized more easily by marking a pre-assignedsymbol on the surface of at least one of the conductive layers 110, forexample, the conductive layer 110 with a mark is presumed to be apositive (+) polarity electrode.

In addition, the chip substrate 100 according to the present exemplaryembodiment may further include a plurality of side grooves 190, 192 anda bolting portions 230,

The side grooves 190, 192 according to the present exemplary embodimentwill be described with reference to FIG. 4. FIG. 4 is a structure of achip substrate for manufacturing unit chip substrates as shown in FIG.1; the structure is designed to include five unit chip substratesaccording to FIG. 4. That is, each of the unit chip substrates as shownin FIG. 1 is being manufactured by cutting the chip substrate shown inFIG. 4.

Therefore, due to cutting, burrs can be generated during sawing ordicing process, so there have been problems of failures such as shortand the like due to the insulation breakdown caused by burrs adhering tothe insulation layer which is a very thin layer.

For solving such problems, the chip substrate 100 according to thepresent exemplary embodiment includes a plurality of through-holes 190,192, as shown in FIG. 4, in the area accommodating insulation layerswhen being cut so that a plurality of side grooves 190, 192 are formedwhen being cut as shown in FIG. 1. That is, the portions wherein thethrough-holes are formed are being present as empty spaces during thesawing or dicing process, therefore burrs are not generated.

In addition, in the chip substrate 100 according to the presentexemplary embodiment, a plurality of bolting portions 230 are formed sothat the chip substrates can be bonded more easily through bolting whenthe chip substrates are being bonded to other PCB substrates. Thebolting portions are structured to have the shape of a through-hole 230as shown in FIG. 4, the bolting portions 230 as shown in FIG. 1 can beobtained after cutting.

In FIG. 4, a plurality of grooves 240 may be used for fixing the chipsubstrate when cutting the chip substrate. That is, cutting is performedafter fixing the chip substrate with pins being inserted into thegrooves 240, so that the chip substrate shown in FIG. 1 can bemanufactured.

FIG. 2 illustrates the rear surface of the chip substrate according tothe present exemplary embodiment; a heat radiating portion (not shown)may further be included in the bottom surface of the chip substrateaccording to the present exemplary embodiment.

That is, a heat radiating portion may be bonded to the bottom surface ofthe chip substrate 100 in order to radiate the heat generated from thechip after an optical device chip is mounted inside the cavity 130.

At this time, the heat radiating portion may be comprised of: a heatradiating interface portion which is being boned to the insulation layer120 and the conductive layer 110 in the bottom surface of the chipsubstrate 100; and a heat diffusing portion which is bonded to the heatradiating interface portion and radiating the generated heat. At thistime, the heat radiating interface portion 152 made of thermal interfacematerial (TIM) having heat dissipation function may be comprised of aninsulator to obtain both insulation and heat radiation capabilities; anda heat diffusing portion comprising metal sheet such as copper,aluminum, or the like may further be included under the heat radiatinginterface portion

Therefore, preferably the thickness of the heat radiating interfaceportion is thin considering the heat radiating characteristics.

The above described chip substrate is devised to solve the difficultiesin manufacturing process wherein the shape of the lens should be formedin the shape of a circle according to the circular chip mounting spaceof the prior art.

According to the present exemplary embodiment, a lens insert comprisingstraight lines is formed prior to forming a circular cavity whereinchips are mounted, so that the lens can be formed to be a shapecomprising straight lines such as a rectangle, thereby making theprocess simpler.

Further, arcs are formed at the corners where the edges of the lensinsert meet so that the cutting machine can be moved from edge to edgemore easily when making the groove of the lens insert, and besides, thebonding process of the lens can be more facilitated by forming separatejig grooves in the edges. Furthermore, according to embodiments of thepresent invention, a plurality of chips being mounted can be connectedin a serial-parallel manner by implementing a structure wherein aplurality of optical chips can be mounted in a single substrate. Thus,the amount of supply current can be reduced compared to the structureimplemented in a parallel manner, and the power consumption can bereduced eventually. Further, the damage of the insulation layer due tothe burrs generated from the cutting process can be prevented throughthe grooves formed in the side surfaces of the chip substrate, andbesides, the heat radiating effect can be enhanced through the heatradiating portion being bonded to the bottom surface of the chipsubstrate.

Above description is merely an exemplary description of the technicalspirit of the present invention, and various modifications, changes, andsubstitutions are possible for a person of skill in the art within thescope without deviating from the fundamental characteristics of thepresent invention.

Therefore, the exemplary embodiment and the accompanying drawingsdisclosed in the present invention is for explanation and not forlimiting the technical spirit of the present invention, and the scope ofthe technical spirit of the present invention is not limited by theseexemplary embodiments and the accompanying drawings. The scope ofprotection of the present invention must be interpreted according to thefollowing claims, and it must be interpreted in such a way that all thetechnical spirits within the equivalent scope of the present inventionare included in the scope of the rights of the present invention.

Advantageously, when the space for lens insertion is formed to be ashape comprising straight lines, the lens to be inserted also can beformed to be a shape comprising straight lines so that the manufacturingprocess of the lens to be inserted into the chip substrate can befurther simplified.

Furthermore, by providing a plurality of joining grooves the adhesiveoverflowing from one of the joining grooves is being accommodated by theother joining groove, therefore the problem of the adhesive penetratinginto the light emitting section of the chip substrate can be resolved.

What is claimed is:
 1. A chip substrate provided with a plurality ofjoining grooves inside the lens insert comprising: a plurality ofconductive layers horizontally stacked and constituting said chipsubstrate; a plurality of insulation layers alternately with saidconductive layers and electrically separating said conductive layers; alens insert comprising a groove having a predetermined number of edgeson the upper surface of said chip substrate and having a cross-sectionwherein an arc is formed at the region where the extended edges meet; acavity comprising a groove reaching down to a predetermined depthtowards the area accommodating said insulation layer within the internalregion of said lens insert; and a plurality of joining grooves formed onthe surface of said lens insert.
 2. The chip substrate provided with aplurality of joining grooves inside the lens insert according to claim1, further comprising: a first metal pad formed on a unit area on saidconductive layers being separated by at least one of said insulationlayers inside said cavity.
 3. The chip substrate provided with aplurality of joining grooves inside the lens insert according to claim1, further comprising: a second metal pad being successively formed onthe plurality of insulation layers separated from the plurality ofinsulation layers inside said cavity.
 4. The chip substrate providedwith a plurality of joining grooves inside the lens insert according toclaim 1, wherein said joining grooves include: a first joining groovebeing formed surrounding the outer area of said cavity on the surface ofsaid lens insert; and a second joining groove being formed surroundingsaid first joining groove.
 5. The chip substrate provided with aplurality of joining grooves inside the lens insert according to claim1, wherein said chip substrate further includes: a heat radiatingportion being attached to the bottom surface of said chip substrate. 6.The chip substrate provided with a plurality of joining grooves insidethe lens insert according to claim 2, wherein said chip substratefurther includes: a plurality of marking portions to indicate said unitareas inside said cavity.
 7. The chip substrate provided with aplurality of joining grooves inside the lens insert according to claim1, wherein said chip substrate further includes: an electrode markingportion to indicate an electrode for at least any one conductive layerseparated from said conductive layers by said insulation layer on theupper surface of said chip substrate.
 8. The chip substrate providedwith a plurality of joining grooves inside the lens insert according toclaim 1, wherein said chip substrate further includes: a plurality ofside grooves, at the side surfaces of said chip substrate, inwardlyconcave and accommodating said insulation layers.